Abstract: A manufacturing method of circuit structure embedded with heat-dissipation block including the following steps is provided. A core board including a first dielectric layer and two first conductive layers located on two opposite sides of the first dielectric layer is provided. A through hole penetrated the core board is formed. A heat-dissipation block is disposed into the through hole. Two inner-layer circuits are formed on two opposite sides of the core board. At least one build-up structure is bonded on the core board, wherein the build-up structure includes a second dielectric layer and a second conductive layer, and the second dielectric layer is located between the second conductive layer and the core board. A cavity is formed on a predetermined region of the build-up structure, and the cavity is communicated with the corresponding inner-layer circuit. Another manufacturing method of circuit structure embedded with heat-dissipation block is also provided.

Abstract: A process planning apparatus based on augmented reality (AR) includes: a camera set capturing color and depth images of a processing machine and a probe operated by a human user in a real scene; a processor, which is signal-connected to the camera set and the processing machine, creates spatial intelligences for motion planning of the probe operated by the human user in an AR environment that combines a virtual workpiece with the real scene, and generates instructional data from the spatial intelligences to guide the human user to operate the probe to produce machine motion data for a manufacturing task; and an output interface, which is signal-connected to the processor and outputs scene data, the virtual workpiece and the instructional data to the human user.

Abstract: The present invention provides a waterborne composition for preventing contact between acnes and irritants, and the water based composition includes a polymer (A), a thickener (B), a functional additive (C) and water (D). The present invention further provides a transparent film and a method of forming the same for preventing contact between acnes and irritants.

Abstract: A vertical probe device includes a lower die having engaging holes and needle holes, a positioning film having limiting holes and needle holes, probe needles inserted through the needle holes, and supporters having at least an upper stopping surface and at least a lower stopping surface for moveably limiting the positioning film therebetween. Each supporter has a head, a neck passing through the limiting hole and having a length longer than the thickness of the positioning film, a body, and a tail inserted into the engaging hole, which are connected in order, and at least one of the upper and lower stopping surfaces. The supporters can prevent the positioning film from being lifted and flipped over and enables the positioning film to move so that the probe needles are reliable.

Abstract: A probe head includes a probe base, a film, and a probe assembly. The probe base includes first, second, and third guiding boards. The second guiding board is fixed between the first and third guiding boards. The film is fixed to the probe base and has a hole. The probe assembly passes through the first, second, and third guiding boards and the hole, and includes a probe and an outer spring sleeve. The probe has a tip passing out through the third guiding board. The outer spring sleeve is sleeved at the exterior of the probe and has a spring area and a plurality of non-spring areas. The spring area is disposed between adjacent two of the non-spring areas. One of the non-spring areas has a bonding section mounted to the probe and retained between the third guiding board and the film.

Abstract: A wavelength-converting polymer, a method for fabricating the same and a wavelength-converting device employing the same are provided. The wavelength-converting polymer has a chemical structure represented by formula (I): In formula (I), B and D are the same or different and independently include hydrogen, C1-8 alkyl group, C1-8 alkoxy group, aryloxy group, carboxyl group, —COOK, —COONa or —NH2, or B and D are connected to form a heteroaromatic ring, wherein Z is hydrogen, C1-8 alkyl group, cycloalkyl group or aryloxy group, X1-X4 are the same or different and independently include hydrogen, halogen, C1-8 alkyl group or C1-8 alkoxy group, R is C1-8 alkyl group with or without substitution, and n is an integer of 5 to 1,000.

Abstract: An apparatus for detecting an object capable of emitting light. The apparatus includes a light source and a waveguide. The waveguide includes a core layer and a first cladding layer. At least one nanowell is formed in at least the first cladding layer. The apparatus further includes a light detector. The light detector can detect a light emitted from a single molecule object contained in the at least one nanowell.

Abstract: An apparatus for detecting an object capable of emitting light. The apparatus comprises a light detector comprising at least two optical sensors capable of determining the intensity of the light; and a computer processing output signal generated by the optical sensors and comparing a result of the processing with a known result corresponding to a known type to determine whether the object belongs to the known type.

Abstract: A detecting device includes at least one detecting module. In the detecting module, a light source unit is configured to emit a first beam and a second beam. The wavelength of the first beam is different from that of the second beam. A packaging unit is disposed on the light source unit and a light detecting unit and on transmission paths of the first beam and the second beam from the light source unit. An optical microstructure unit is disposed on the transmission paths of the first beam and the second beam. The first beam and the second beam emitted from the light source unit pass through the packaging unit to pass the optical microstructure unit to be transmitted to a biological tissue, and then pass through the optical microstructure unit to pass the packaging unit to be transmitted to the light detecting unit in sequence.

Abstract: An apparatus for non-invasive blood glucose monitoring includes a light source for generating at least one ray of light, a beam splitter with a focusing function leads the light into an eyeball and focuses on the eyeball, a set of photo detectors for measuring optical angular information and absorption energy information of the light reflected from the eyeball and transmitted through the first beam splitter to the set of photo detectors, and a processing unit. The processing unit receives and processes the Optical angular information and the absorption energy information to obtain an Optical angular difference and an absorption energy difference between the light emitted from the light source and the light transmitted to the set of photo detectors, and analyzes the Optical angular difference and the absorption energy difference to obtain a glucose information, and since the glucose information has a corresponding relationship with a blood glucose information, the blood glucose information may be read.

Abstract: A wafer testing probe card includes a printed circuit board, a flexible circuit board, an elastic piece, and a probe unit. The flexible circuit board is electrically connected to the printed circuit board. The elastic piece is disposed between the printed circuit board and the flexible circuit board. The probe unit includes a probe head and a plurality of probes. The probe head is fixed on the printed circuit board and has a plurality of through holes. The probes respectively pass through the through holes and move up and down relative to the probe head.

Abstract: An apparatus for detecting an object capable of emitting light. The apparatus comprises a light detector comprising at least two optical sensors capable of determining the intensity of the light; and a computer processing output signal generated by the optical sensors and comparing a result of the processing with a known result corresponding to a known type to determine whether the object belongs to the known type.

Abstract: Embodiments encompass a single-molecule detection system and methods of using the detection system to detect an object. Further, embodiments encompass a detection system comprising a movable light coupler, a waveguide, and a light detector. Embodiments further encompass methods of single-molecule detection, including methods of single-molecule nucleic acid sequencing.

Abstract: A method for non-invasive blood glucose monitoring includes the following steps. At least one ray of light is emitted from at least one light source. The light emitted from the light source is leaded into an eyeball and focused on the eyeball through a first beam splitter. The reflected light reflected from the eyeball is transmitted through the first beam splitter to a set of photo detectors. Optical angular information and absorption energy information of the reflected light transmitted to the set of photo detectors are measured. Optical angular difference and absorption energy difference resulting from the light emitted from the light source and the reflected light transmitted to the set of photo detectors are obtained. Glucose information is obtained by analyzing the optical angular difference and the absorption energy difference, and since glucose information has a corresponding relationship with blood glucose information, blood glucose information may be read.

Abstract: An apparatus for non-invasive glucose monitoring includes a light source for emitting at least one ray of light; a first beam splitter, a set of photo detectors for measuring optical rotatory distribution (ORD) information and absorption energy information; a reference component receiving the light from the first beam splitter, and the light reflected by the reference component being transmitted to the set of photo detectors by the first beam splitter, wherein the light emitted from the light source is transmitted to the set of photo detectors by the first beam splitter and the eyeball to form a first optical path, the light emitted from the light source is transmitted to the set of photo detectors by the first beam splitter and the reference component to form a second optical path; and a processing unit receiving and processing the ORD information and the absorption energy information to obtain a glucose information.

Abstract: An apparatus for non-invasive glucose monitoring includes a first light source for emitting at least one ray of first light; a first beam splitter with a focusing function; a set of photo detectors for measuring optical rotatory distribution (ORD) information and absorption energy information of the first light reflected from the eyeball and transmitted through the first beam splitter to the set of photo detectors, and the first light emitted from the first light source being transmitted to the set of photo detectors by the first beam splitter and the eyeball to form an optical path; a processing unit receiving and processing the ORD information and the absorption energy information to obtain glucose information; and an eye positioning device including a second beam splitter disposed on the optical path between the first beam splitter and the eyeball and a camera for receiving image information transmitted from the second beam splitter.

Abstract: A probe head includes a probe base, a film, and a probe assembly. The probe base includes first, second, and third guiding boards. The second guiding board is fixed between the first and third guiding boards. The film is fixed to the probe base and has a hole. The probe assembly passes through the first, second, and third guiding boards and the hole, and includes a probe and an outer spring sleeve. The probe has a tip passing out through the third guiding board. The outer spring sleeve is sleeved at the exterior of the probe and has a spring area and a plurality of non-spring areas. The spring area is disposed between adjacent two of the non-spring areas. One of the non-spring areas has a bonding section mounted to the probe and retained between the third guiding board and the film.

Abstract: A positioner and a probe head of a probe card are provided. The positioner has a main opening, a first sub-opening, a second sub-opening, a third sub-opening, a fourth sub-opening, a first positioning portion, a second positioning portion, a first elastic portion and a second elastic portion. The first sub-opening, the second sub-opening, the third sub-opening, and the fourth sub-opening are sequentially arranged at the periphery of the main opening and are communicated to the main opening. A stiffness of the first positioning portion and a stiffness of the second positioning portion are higher than a stiffness of the first elastic portion and a stiffness of the second elastic portion.

Abstract: A probe needle includes a head, a tail and a body connected between the head and the tail and provided with a first flat section curvedly extending from the head towards the tail for providing sufficient deformation when the tail is pressed on a device under test, and a second flat section neighbored to the first flat section for supporting the probe needle in between upper and lower dies. When the probe needles are used in a probe module, the probe needles can be arranged with a pitch same as that of the conventional probe needles even though the probe needles are formed from posts having a relatively greater diameter than that of the posts for making the conventional probe needles, such that the probe needles may have enhanced current withstanding capacity and prolonged lifespan.

Abstract: A spring probe includes a needle, a spring sleeve sleeved onto and fixed to the needle and having non-spring sections and at least one spring section, and an outer sleeve sleeved onto the spring sleeve and covering the at least one spring section. A part of the outer sleeve is connected with the spring sleeve. A probe device includes the spring probe, and a probe seat having dies piled on one another, including upper and lower dies. The spring probe is inserted through the dies in a way that a bottom end of the spring sleeve is abutted on the lower die.